Abstract: An aspect of the invention provides a solar cell that comprises a semiconductor substrate having a light-receiving surface and a rear surface; a first semiconductor layer having a first conductivity type; a second semiconductor layer having a second conductivity type, the first semiconductor layer and the second semiconductor layer being formed on the rear surface, and a trench formed in the rear surface, wherein the first semiconductor layer is formed on the rear surface in which the trench is not formed, and the second semiconductor layer is formed on a side surface of the trench in an arrangement direction in which the first semiconductor layer and the second semiconductor layer are alternately arranged and on a bottom surface of the trench.

Abstract: A solar cell module includes: two solar cells, each including: a first main face and a second main face; a first electrode on the first main face, comprising a bus-bar electrode having at least one of an opening portion, notch portion, and gap portion; and a second electrode on the first or second main face having a polarity opposite to that of the first electrode; a wiring member that electrically connects the first electrode of one solar cell to the second electrode of another solar cell; and an electrically conductive connection layer that contacts the wiring member and the first main face.

Abstract: A solar cell module includes: two solar cells, each including: a first main face and a second main face; a first electrode on the first main face, comprising a bus-bar electrode having at least one of an opening portion, notch portion, and gap portion; and a second electrode on the first or second main face having a polarity opposite to that of the first electrode; a wiring member that electrically connects the first electrode of one solar cell to the second electrode of another solar cell; and an electrically conductive connection layer that contacts the wiring member and the first main face.

Abstract: A solar cell module includes: two solar cells, each including: a first main face and a second main face; a first electrode on the first main face, comprising a bus-bar electrode having at least one of an opening portion, notch portion, and gap portion; and a second electrode on the first or second main face having a polarity opposite to that of the first electrode; a wiring member that electrically connects the first electrode of one solar cell to the second electrode of another solar cell; and an electrically conductive connection layer that contacts the wiring member and the first main face.

Abstract: A solar cell includes semiconductor substrate of a first conductivity type; first semiconductor layer having a first conductivity type; second semiconductor layer having a second conductivity type; first electrode; second electrode; and insulating layer. First semiconductor layer and second semiconductor layer are formed on rear surface. When one end portion of insulating layer which is formed on first semiconductor layer and which is on a side close to first electrode is defined as first insulating-layer end portion and another end portion of insulating layer on a side close to second electrode is defined as second insulating-layer end portion in arrangement direction x, a distance from end point of second-semiconductor-layer end portion in contact with rear surface to second insulating-layer end portion in arrangement direction x is shorter than a distance from end point to first insulating-layer end portion in arrangement direction x.

Abstract: A solar cell includes semiconductor substrate of a first conductivity type; first semiconductor layer having a first conductivity type; second semiconductor layer having a second conductivity type; first electrode; second electrode; and insulating layer. First semiconductor layer and second semiconductor layer are formed on rear surface. When one end portion of insulating layer which is formed on first semiconductor layer and which is on a side close to first electrode is defined as first insulating-layer end portion and another end portion of insulating layer on a side close to second electrode is defined as second insulating-layer end portion in arrangement direction x, a distance from end point of second-semiconductor-layer end portion in contact with rear surface to second insulating-layer end portion in arrangement direction x is shorter than a distance from end point to first insulating-layer end portion in arrangement direction x.

Abstract: An aspect of the invention provides a solar cell that comprises a semiconductor substrate having a light-receiving surface and a rear surface; a first semiconductor layer having a first conductivity type; a second semiconductor layer having a second conductivity type, the first semiconductor layer and the second semiconductor layer being formed on the rear surface, and a trench formed in the rear surface, wherein the first semiconductor layer is formed on the rear surface in which the trench is not formed, and the second semiconductor layer is formed on a side surface of the trench in an arrangement direction in which the first semiconductor layer and the second semiconductor layer are alternately arranged and on a bottom surface of the trench.

Abstract: A solar cell module includes solar cells and a wiring member connecting the solar cells. At least one side portion of the wiring member is bonded to a portion of a first principal surface of the solar cell where both first and second electrodes are provided, by adhesive resin layer. A first portion of the resin adhesive layer, which is located between the at least one side portion of the wiring member and the first electrode is thinner than a second portion of the adhesive resin layer, which is located between the at least one side portion of the wiring member 11 and the second electrode such that the at least one side portion of the wiring member is electrically connected with the first electrode while being electrically insulated from the second electrode.

Abstract: A solar cell module includes: two solar cells that photogenerate carriers, each having a first electrode on a first main face of a photoelectric conversion body, and a second electrode of opposite polarity on a main face; and a wiring member to electrically connect the two solar cells via the respective cell's first and second electrodes. A bus-bar electrode collects photogenerated carriers from the finger electrodes. The wiring member connects to the bus-bar electrode of one solar cell through a conductive resin connection layer. The connection layer also contacts the first main face of the photoelectric conversion body.

Abstract: A p type amorphous silicon layer is stacked, by a CVD method, on a main surface of an n type single-crystalline silicon substrate; an n type amorphous silicon layer is stacked, by the CVD method, on a surface opposite to the surface on which the p type amorphous silicon layer is stacked; and, by using a laser ablation processing method, through-holes are formed in the n type single-crystalline silicon substrate, the p type amorphous silicon layer, and the n type amorphous silicon layer. Subsequently, an insulating layer is formed on an inner wall surface of each of the through-holes, and then a conductive material is filled therein.

Abstract: Provided is a solar cell in which a linear n finger electrode and a linear p finger electrode are alternately arranged on a projection plane parallel to a main surface of a substrate, and which is arranged in a predetermined arrangement direction, including an n-side bus bar electrode connected to the n finger electrode and insulated from the p finger electrode and a p-side bus bar electrode connected to the p finger electrode and insulated from the n finger electrode. The n-side bus bar electrode and the p-side bus bar electrode are provided on a same main surface side of the substrate, intersect with the n finger electrode and the p finger electrode respectively on the projection plane, and have a slope angle relative to the predetermined arrangement direction.

Abstract: A p type amorphous silicon layer is stacked, by a CVD method, on a main surface of an n type single-crystalline silicon substrate; an n type amorphous silicon layer is stacked, by the CVD method, on a surface opposite to the surface on which the p type amorphous silicon layer is stacked; and, by using a laser ablation processing method, through-holes are formed in the n type single-crystalline silicon substrate, the p type amorphous silicon layer, and the n type amorphous silicon layer. Subsequently, an insulating layer is formed on an inner wall surface of each of the through-holes, and then a conductive material is filled therein.

Abstract: To suppress a decrease in power collection efficiency, provided is a solar cell module including; first and second solar cells arranged in a first direction; and a wiring member electrically connecting the first and second solar cells. In the solar cell module, the first and second solar cells each include a light-receiving surface receiving light, a back surface provided on the opposite side of the light-receiving surface, and p-side and n-side electrodes formed on the back surface; the wiring member is connected to the n-side electrode of the first solar cell at a first connecting point, and connected to the p-side electrode of the second solar cell at a second connecting point; and, in a planar view of the back surface, the first and second connecting points are located on a line intersecting with the first direction.

Abstract: Provided is a solar cell in which a linear n finger electrode and a linear p finger electrode are alternately arranged on a projection plane parallel to a main surface of a substrate, and which is arranged in a predetermined arrangement direction, including an n-side bus bar electrode connected to the n finger electrode and insulated from the p finger electrode and a p-side bus bar electrode connected to the p finger electrode and insulated from the n finger electrode. The n-side bus bar electrode and the p-side bus bar electrode are provided on a same main surface side of the substrate, intersect with the n finger electrode and the p finger electrode respectively on the projection plane, and have a slope angle relative to the predetermined arrangement direction.

Abstract: A solar cell having a through-hole electrode with an improved manufacturing yield is provided. The solar cell includes a through-hole passing through a photoelectric converter from a light-receiving surface to the back surface of the photoelectric converter. One end portion on the back surface side of the through-hole branches off in multiple back surface side branch portions and the back surface side branch portions open on the back surface of the photoelectric converter.

Abstract: The first and second solar cells are arranged to be adjacent to each other in the arrangement direction. On the back surface of the first solar cell, the multiple first n-type regions are formed in the arrangement direction and the multiple first p-type regions are formed between each of the multiple first n-type regions. On the back surface of the second solar cell, the multiple second p-type regions are formed in the arrangement direction and the multiple second n-type regions are formed between each of the multiple second p-type regions. Each of the multiple first n-type regions and each of the multiple second p-type regions are formed on the back surface in a substantially straight line. Each of the multiple first p-type regions and each of the multiple second n-type regions are formed on the back surface in a substantially straight line.

Abstract: A solar cell module includes: two solar cells, each including an photoelectric conversion body 10a, 10b having first and second main faces and generating photogenerated carriers, a first electrode provided on the first main face, and a second electrode provided on the first or second main face and having a polarity opposite to that of the first electrode; and a wiring member 2a for electrically connecting the first electrode of one of the two solar cells to the second electrode of the other solar cell. The first electrode has a plurality of finger electrodes for collecting the photogenerated carriers generated in the photoelectric conversion body 10a and a bus-bar electrode 11a for collecting the photogenerated carriers collected by the plurality of finger electrodes. The wiring member 2a is connected onto the bus-bar electrode 11a of the one solar cell through a connection layer 13 formed of a conductive resin containing conductive material.

Abstract: An object formed of a semiconductor is heated to and kept at such a temperature that a semiconductor crystal formed of a II-VI Group compound semiconductor mainly containing Zn and Se can be grown. A molecular beam including elements constituting the II-VI Group compound semiconductor mainly containing Zn and Se is irradiated onto the heated object, and a gas beam composed of a nitrogen molecule being in a ground electronic state and having a gas pressure of not less than 3.times.10.sup.-5 Torr, to form a p-type semiconductor crystal on the object.